Methods and systems for electrochemically producing at least one product are disclosed. In some embodiments, the systems include a membraneless electrochemical flow-through reactor. A pair of porous electrodes configured at an angle to each other is disposed within the reactor in a channel of flowing electrolyte including a target reactant. As the electrolyte stream flows through the porous electrodes, a voltage is applied across the electrodes, resulting in the generation of a catholyte effluent stream and an anolyte effluent stream Gaseous and/or liquid products may then be separated from these streams. The membraneless electrochemical flow-through reactor is an easy to design and assemble apparatus for a variety of electrochemical processes.
|
1. An electrochemical flow-through reactor comprising:
a channel for containing and directing flow of a matter stream, wherein said matter stream includes at least one reactant;
at least one anode and at least one cathode positioned laterally adjacent and obliquely to each other at a location within said channel and extending longitudinally along said channel; and
a plurality of effluent flow channels downstream of said channel, said plurality of effluent flow channels separated by a divider, and said at least one anode and said at least one cathode separated by the divider,
wherein said oblique at least one anode and at least one cathode are porous, in fluid communication with said matter stream, connected to the divider and a wall of said channel, and arranged within said channel such that said matter stream flows through said at least one anode and at least one cathode.
2. The electrochemical reactor according to
3. The electrochemical reactor according to
4. The electrochemical reactor according to
5. The electrochemical reactor according to
6. The electrochemical reactor according to
7. The electrochemical reactor according to
8. The electrochemical reactor according to
9. The electrochemical reactor according to
10. The electrochemical reactor according to
12. The electrochemical reactor according to
|
This application claims the benefit of U.S. Provisional Application No. 61/220,707, filed Sep. 18, 2015, and U.S. Provisional Application No. 61/303,912, filed Mar. 4, 2016, which are incorporated by reference as if disclosed herein in their entirety.
Electrolysis is a very important industrial process used to produce a variety of vital chemical building blocks. Processes such as the chlor-alkali process, electro-synthesis of anthraquinone, and electro-fluoridation all play essential roles in the production of chemicals used in our everyday lives. Electrolysis can be an energy efficient process with a significantly lower carbon footprint compared to traditional thermal catalysis processes if the input electricity is derived from a renewable resource such as wind or solar. As of 2006, chemical production by electrochemical processes made up more than 6% of the total electrical generating capacity of the United States, with the most energy intensive process as being performed by the chlor-alkali industry. These processes are used to produce hydrogen gas, caustic soda (sodium hydroxide), and chlorine gas. For the chlor-alkali processes, and most electrolysis processes, the economics are dominated by the cost of electricity, which accounts for a significant fraction of the total manufacturing cost. However, the decreasing costs of electricity from renewable resources and the continued adoption of time-of-use pricing schemes are likely to change the economics of electrochemical processes, shifting importance towards decreasing the capital cost of the electrolyzer system itself.
The process chemistry of the chlor-alkali process is relatively simple but the operational and reactor design issues are vastly complex. The most energy efficient electrolyzer in the chlor-alkali industry is the membrane electrolyzer. The membrane electrolyzer functions by separating anolyte and catholyte streams by means of an ion selective membrane and that only allows cationic species (e.g. Na+, K+, H+) and small amounts of water to pass through it. Diaphragm electrolyzers and mercury electrolytic cells are also used to produce bases, although these technologies are being phased out in favor of membrane reactors. This is due to health and environmental concerns relating to the use of asbestos and mercury, respectively. Key challenges with membrane electrolyzers include the high cost of the ion-selective membranes and their susceptibility to fouling. Various approaches have been pursued in order to improve the yield, energy efficiency, economics, and environmental impacts of the membrane process.
What is desired, therefore, is the development of simple, scalable, and efficient electrolysis devices that are suitable for a variety of electrochemical processes. Such devices would greatly reduce material costs at least in part by eliminating the material costs associated with membranes complex manufacturing, and simplify device design and ease of assembly.
Membraneless electrolyzers based on flow-through mesh electrodes were systematically investigated as a means of simultaneously producing hydrogen, acid, and base. Unlike traditional chlor-alkali electrolyzers, which use diaphragms or ion-selective membranes to separate products, this design employs flow-induced product separation in conjunction with porous mesh flow-through electrodes to separate oxidation and reduction products. In some embodiments, the electrolyzer includes a 3D printed reactor body. In some embodiments, the reactor is fabricated out of poly (lactic acid) (PLA). By systematically varying the electrolyte flow rate and operating current, it is shown that these electrolyzers are well-suited to achieve excellent control over the pH of the cathode and anode effluent streams. Starting with pH neutral 1 M brine (KNO3 or Na2SO4), pH differences as high as 10 pH units were produced between the product streams. The reactors consistent with embodiments of the present disclosure enable innovative membraneless electrolysis strategies for low-cost and efficient production of a variety of chemicals in which alkaline and/or acidic environments are required.
The reactors of the present disclosure substantially decrease both material and assembly cost while also enabling co-production of acid, base, and H2. These electrolyzers operate without membranes due to the use of angled flow-through electrodes combined with flow-induced separation of products before they can cross over between anolyte and catholyte effluent streams. In some embodiments, the electrochemical reactors of the present disclosure are comprised of only three required components: the anode, cathode, and cell body. The simplicity of this design allows it to be fabricated by low-cost manufacturing techniques (e.g. injection molding) and thereby offers great promise for decreasing the capital costs associated with electrolysis processes.
Acids and bases are formed by varying the current densities through the electrodes and the flow rate of the electrolyte through the flow cell. The electrolyte for these experiments were adjusted to a near-neutral pH. pH values as low as 3 and as high as 12 are achievable at a current density of 208 mA cm−2. The pH of the downstream channels of the electrolyzer can be predicted by using Faraday's law of electrolysis and measurements were reproducible. The product crossover of the cell was measured visually by colorimetry using a universal pH indicator. The results of this investigation indicated low product crossover in this electrolyzer and also confirmed the pH readings by the pH meter. This electrolyzer provides a cheaper alternative to producing acid and base with low CO2 emissions when powered by a renewable energy source.
In some embodiments, the present disclosure is directed to an electrochemical flow-through reactor comprising a channel for containing and directing a flow of at least one matter stream, wherein the at least one matter stream includes at least one reactant, and at least two oblique electrodes positioned at a location within the channel, wherein the at least two oblique electrodes are porous, in fluid communication with the matter stream, and arranged within the channel such that the matter stream flows through the at least two electrodes. In some embodiments, the at least two electrodes are at least one anode and at least one cathode. In some embodiments, the angle between the at least two oblique electrodes is selected from the group consisting of: 180°, 90°, 60°, and 30°.
In some embodiments, the electrochemical flow-through reactor comprises a divider downstream of the at least one anode and the at least one cathode. In some embodiments, a plurality of electrochemical flow-through reactors are arranged in series and in fluid communication. In some embodiments, at least one electrode includes a catalyst. In some embodiments, at least one electrode is mesh shaped as a ring, wire, disk, band, or plate.
In some embodiments, the electrochemical reactor comprises an anolyte product collector and a catholyte product collector in fluid communication with the channel. In some embodiments, the channel has an annular conformation comprising a porous central conduit and an outer wall, wherein the at least two oblique electrodes are disposed between the central conduit and the outer wall. In some embodiments, the matter is selected from the group consisting of: gas, liquid, and mixed-phase electrolyte. In some embodiments, the matter is an electrolyte.
In some embodiments, the present disclosure is directed to a method of electrochemically producing at least one product comprising the steps of providing a channel, flowing a matter stream including at least one reactant through the channel, providing at least two electrodes within the channel and in fluid communication with the matter stream, wherein the at least two electrodes are porous, applying a voltage across the at least two electrodes, flowing the matter stream through the porous electrodes, and isolating an effluent stream enriched for the at least one reactant.
In some embodiments, the method further comprises providing a divider downstream from the at least two electrodes, wherein the divider separates a first effluent stream from a second effluent stream. In some embodiments, the method further comprises recovering an amount of the at least one reactant from at least one of the first effluent stream and the second effluent stream as an at least one product. In some embodiments, the method further comprises recycling the matter stream after recovering the at least one product. In some embodiments, the flow is pulsed. In some embodiments, the voltage is pulsed.
In some embodiments, the present disclosure is directed to an electrolyzer system comprising an electrolyte reservoir, a reactant reservoir, a flow-through reactor comprising a channel for containing and directing a flow of the at least one electrolyte stream through at least two oblique electrodes, at least one inlet stream in upstream fluid communication with the electrolyte reservoir and the reactant reservoir and in downstream fluid communication with the flow-through reactor, an electrolyte stream comprising at least one electrolyte and at least one reactant, a first effluent stream, a second effluent stream, and an electrolyte recycle stream in fluid connection with the first effluent and the second effluent streams.
In some embodiments, the first effluent stream includes a catholyte product and the second effluent stream includes an anolyte product. In some embodiments, the electrolyzer system further comprises at least one liquid/gas separator configured to produce at least one product stream, wherein the product in the at least one product stream is selected from the group consisting of: the catholyte product and the anolyte product.
In some embodiments, the channel has an annular conformation comprising a porous central conduit and an outer wall, wherein the at least two oblique electrodes are disposed between the central conduit and the outer wall.
The drawings show embodiments of the disclosed subject matter for the purpose of illustrating the invention. However, it should be understood that the present application is not limited to the precise arrangements and instrumentalities shown in the drawings, wherein:
Referring to
In some embodiments, electrolyzer system 1 comprises at least one inlet stream 103. In some embodiments, the flow rate of at least one inlet stream 103 is substantially constant. In some embodiments, the flow rate of at least one inlet stream 103 is pulsed. At least one inlet stream 103 comprises matter to be reacted in membraneless electrochemical flow-through reactor 100. In some embodiments, at least one inlet stream 103 comprises at least one electrolyte. In some embodiments, at least one inlet stream 103 comprises at least one reactant. In some embodiments, the reactant is water. In some embodiments, at least one inlet stream 103 comprises at least one electrolyte and at least one reactant.
In some embodiments, at least one inlet stream 103 enters membraneless electrochemical flow-through reactor 100 and flows along a channel 104. In some embodiments, the size and shape of channel 104 are any size and shape suitable to convey at least one inlet stream 103 to electrodes 105 and 106. In some embodiments, at least one of electrodes 105 and 106 is a cathode. In some embodiments, at least one of electrodes 105 and 106 is an anode. In some embodiments, at least one of electrodes 105 and 106 are porous. The following description refers to an exemplary embodiment of the instant disclosure where electrode 105 is the cathode and electrodes 106 is the anode, though the designation of 105 as the cathode and 106 as the anode is intended to be non-limiting. In some embodiments, system 1 includes multiple pairs of electrodes 105 and 106. Designs incorporating multiple pairs of electrodes can benefit from higher efficiency evolution of target product. Increasing the contact area between at least one inlet stream 103 and electrodes 105 and 106 results in corresponding increases in product evolution and output. Thus, membraneless electrochemical flow-through reactor 100 is advantageously scalable by simply increasing the total area of the electrodes. In some embodiments, electrodes are stacked to enable inducing higher current densities through the electrodes. In some embodiments, at least one electrode includes electrodeposited platinum on titanium.
In some embodiments, at least one inlet stream 103 flows through at least one of cathode 105 and anode 106. When a voltage is applied across cathode 105 and anode 106 as at least one inlet stream 103 flows through those electrodes, a redox reaction occurs resulting in the generation of catholyte at cathode 105 and anolyte at anode 106. In some embodiments, the applied voltage is substantially constant. In some embodiments, the applied voltage is pulsed. In some embodiments, the voltage is applied by power source 117. In some embodiments, channel 104 includes a divider 116 positioned to facilitate separation of a catholyte effluent stream 107 and an anolyte effluent stream 108. In some embodiments, the divider is at least 1 mm thick. In some embodiments, the divider is any suitable shape to facilitate separation of catholyte effluent stream 107 and anolyte effluent stream 108 downstream of electrodes 105 and 106 while limiting crossover between the effluent streams.
In some embodiments, system 1 includes at least one sensor. In some embodiments, the sensor is upstream of electrodes 105 and 106. In some embodiments, the sensor is downstream of electrodes 105 and 106. In some embodiments, the at least one sensor is a chemical, electrochemical, mechanical, or physical sensor, and combinations thereof and the like. In some embodiments, the sensor, is a pH sensor,
In some embodiments, catholyte effluent stream 107 is enriched for a catholyte. In some embodiments, anolyte effluent stream 108 comprises a base. In some embodiments, anolyte effluent stream 108 is enriched for an anolyte. In some embodiments, anolyte effluent stream 108 comprises an acid. In some embodiments, catholyte effluent stream 107 comprises a first product 110. In some embodiments, anolyte effluent stream 108 comprises a second product 111. In some embodiments, the products are isolated from the effluent streams with separators 109.
In some embodiments, electrolyzer system 1 includes a recycle stream 112 for recycling electrolyte solution from membraneless electrochemical flow-through reactor 100 to electrolyte reservoir 101. In some embodiments, electrolyzer system 1 includes a plurality of pumps 114 to move matter streams throughout the system. In some embodiments, a valve 113 controls flow of reactant to at least one inlet stream 103. In some embodiments, electrolyzer system 1 includes a controller 115. In some embodiments, controller 115 controls at least one of reactant flow rate, reactant concentration, pulse time, sensors, and the like.
Referring to
Referring again to
Referring to
One important advantage of membraneless electrolyzers is that they can be electrolyte agnostic so long as the electrolyte possesses sufficient ionic conductivity to maintain acceptable ohmic solution losses. In the following example, the versatility of the membraneless electrolyzer to operate in potassium nitrate (KNO3) and sodium sulfate (Na2SO4) brine solutions is demonstrated, which allows for simultaneous production of acid and base. As illustrated in
2H2O+2e−↔H2+2OH− (1)
2H2O↔4H++O2+4e − (2)
During operation, the products from reactions (1) and (2) are immediately swept downstream of the electrodes, preventing transport and recombination of the H+and OH− ions that would normally occur in a stagnant electrolyte in the absence of a membrane. By varying operating parameters such as the current density passed through the electrodes and the flow rate of the electrolyte through the electrolyzer cell, it is possible to produce acid and base at a desired pH.
In some embodiments, the present disclosure is also directed to methods of electrochemically producing at least one product. As portrayed in
In some embodiments, the method comprises applying 503 a voltage across the at least two electrodes. In some embodiments, the method comprises the step of flowing 504 the matter stream through the porous electrodes. In some embodiments, the method comprises isolating 505 an effluent stream enriched for the at least one reactant.
As portrayed in
As portrayed in
In some embodiments, such as those portrayed at
Referring to
In this embodiment, the electrolyzer has been fabricated by 3D printing and the electrodes utilized in this cell are platinized titanium mesh arranged at an angle of 180° to each other. The electrodes are 0.6 cm2 in length and have a cross sectional area of 0.24 cm2.
The catalytic activity of the platinized electrodes towards the hydrogen and oxygen evolution reactions (Eq. 1 and 2, respectively) was evaluated outside the flow cell by means of cyclic voltammetry (CV) in a 0.5 M H2SO4, 1 M Na2SO4 (adjusted to pH 7) and 1 M KNO3 (pH 7) electrolytes (
The electrodes were also characterized in all the electrolyte solutions listed above using a two electrode arrangement with a platinized titanium mesh as a counter electrode. pH 7 solutions were used in this experiment as pH changes are easier to measure when starting with a neutral pH solution. As observed in
Referring to
By varying the flow rate of electrolyte through the cell and the current applied through the electrodes a pH difference between the two product streams (anolyte effluent and catholyte effluent) can be achieved. To predict the resultant pH of both streams, Faraday's law in conjunction with the electrolyte flow rate can be utilized:
where, J is the current density (C s−1 cm−2), A is the cross sectional area of the effluent channel (cm2), n is the number of electrons involved in the redox reaction, F is Faraday's constant (96485 C mole−1), and v is the volumetric flow rate (cm3 s−1).
In order to determine the pH change between the neutral inlet stream and the effluent streams, the two effluent streams were separately collected and their pH analyzed using a commercial pH probe. The electrolyzer was operated using two different reactant solutions (1.0 M KNO3 and 1.0 M Na2SO4), for which the initial pH was adjusted to a value of approximately 7 for all experiments performed. In these experiments, the effect of flow rate and current density on the pH of the catholyte and anolyte streams was measured.
As expected, the pH of the cathode stream increases with increasing current density (Eq. 3), and the pH of the anode stream decreases with increasing current density. As shown in FIG, 10, the measured pH values agree well with the calculated values on both the anode and cathode streams at the higher current densities and using 1.0 M KNO3 as the reactant. pH measurements at various current densities and flow rates in KNO3: a.) anode and b.) cathode effluent stream pH values recorded while operating under a flow rate of 0.42 mL s−1; c.) anode and d.) cathode effluent stream pH values recorded while operating the cell at a higher flow rate (1.11 mL s−1) The last data point on graphs a and b (at 208 mA cm−2) was performed at 0.62 mL s−1 due to poor bubble detachment from electrodes at 0.42 mL s−1. The change in flow rate is accounted for in the predicted values. At low flow rates and high current densities, gaseous bubbles build up on the electrodes surface leading to decreased device efficiency due to a higher cell resistance and lack of fresh electrolyte being delivered to the Pt—Ti mesh. The expected pH values were calculated based on the electrolyte flow rate and applied current density. However, significant differences between the predicted and measured pH values are observed for the anode stream at lower current densities. On the cathode stream (graph b), the measured pH values are higher than the expected value at current densities higher than 40 mA cm−2. The activity coefficient of protons in KNO3 and Na2SO4 has not been accounted for in the pH calculation above (Eq. 3), this is suspected to be the reason for the pH differences between the measured and calculated values. Including the activity coefficient value to the equation will give higher pH values which will agree better with the measured values.
In order to determine the effect of flow rate on the measured pH, the electrolyzer was operated at a higher flow rate of 1.11 mL s−1 in KNO3 (
Referring to
S2O82−+2e−→2SO42− E0X0=2.01V (4)
The pH measurement for the cathode channel while using Na2SO4 as the electrolyte graph b shows similar results to those recorded with KNO3 indicating both figures show true values. The differences seen between the measured and predicted pH are also attributed to the activity coefficient of protons in Na2SO4.
The error bars on most measurements are small, indicating the results are reproducible. The error associated with the pH meter used in this experiment has not been accounted for, which could also result in higher pH differences between the measured and calculated values.
All solutions were prepared using 18.2 MΩ cm water. Concentrated sulfuric acid (Certified ACS plus, Fisher Scientific Company, Fair Lawn, N.J.), sodium sulfate (ACS Reagent grade, Sigma-Aldrich Co., St. Louis, Mo.), potassium tetrachloroplatinate (99.99% trace metals basis, Sigma-Aldrich Co., St. Louis, Mo.) and potassium nitrate (ReagentPlus 99.0%, Sigma-Aldrich Co., St. Louis, Mo.) were utilized in this project. The electrolyzer was 3D printed (MAKERBOT®, MakerBot Industries, LLC, Brooklyn, N.Y.) from natural color poly(lactic acid) (PLA) filaments. The electrodes were made from titanium mesh (80 mesh; 130 μm wire diameter), purchased from Alfa Aesar, Ward Hill, Mass., and were cut using titanium scissors to an appropriate size. JB Weld 5-minute epoxy (J-B Weld Company, Atlanta, Ga.) was used to seal the electrodes and glass window in place on the electrolyzer body.
The body of the electrolyzer was designed using the AutoDesk Inventor Professional CAD software v2016 (Autodesk, Inc., San Rafael, Calif.). The electrolyzer cell was printed on a MakerBot replicator 2.0 3D printer (MakerBot Industries, LLC, Brooklyn, N.Y.) using PLA filaments. The cell was 3D printed at high resolution, with a 0.1 mm layer height and a 15% infill. The fluidic channel of the flow cell was 7.0 cm long, 1.3 cm wide and 0.5 cm high, with a 3.3 cm by 0.1 cm product divider placed downstream of the electrodes. The cross-section of each product channel was 0.5 by 0.6 cm. The inlet and outlets were 4.0 mm ID. The computer aided design (CAD) file for this electrolyzer is freely available at echem.io. The electrolyzer was assembled by positioning two platinized titanium mesh electrodes at a 180° angle to each other within the printed flow cell. A transparent glass window was placed on the top of the electrolyzer in order to visualize pH changes with a universal pH indicator color changing dye. The Pt/Ti mesh electrodes and glass windows were epoxied to the cell body and given at least 24 hours to set.
Before platinization, the titanium mesh electrodes were cleaned using double-step chronoamperometry in 0.5 M H2SO4. Platinum electrodeposition was carried out by means of CV, with the applied potential cycled 20 times between 0.3 and −0.7 V vs. Ag/AgCl in a solution of 3 mM K2PtCl4 and 0.5 M NaCl (pH=3.1).
All experiments were performed using a Biologic SP-300 or -200 bi-potentiostat/galvanostat. Electrode and electrolyzer performance were characterized by CV and electrochemical impedance spectroscopy. The catalytic activity of the platinized electrodes towards the hydrogen and oxygen evolution reactions (Eq. 1 and 2, respectively) was evaluated outside the flow cell by means of CV in a 0.5 M H2SO4 electrolyte. A three electrode arrangement was utilized with Ag|AgCl half-cell as the reference electrode, and a graphite rod as the counter electrode. All solutions were pumped using a Cole Parmer Masterflex L/S peristaltic pump equipped with an Easy Load II pump head. A home-built dampener was used in all experiments to reduce the level of noise caused by the pulse-flow of the peristaltic pump.
pH measurements were performed using a Fisher Scientific Education bench-top pH meter. The pH meter is calibrated with pH 4.01, 7 and 10.01 buffer solutions (Oakton) at the start of all experiments. The downstream products from the anode and cathode streams were collected in beakers, which were placed directly below the outlets of the flow cell.
Activity coefficients were determined by making solution of known concentrations of acid (HNO3) and base (KOH) and mixing this with a fixed volume of 1M solution of KNO3. The pH of the resultant mixture was then measured and a plot of the pH against concentration of acid/base was made.
Referring to
With higher current densities, the pH difference between the anode and cathode streams can be maximized, leading to more applications of this electrolyzer in various industries.
Although the disclosed subject matter has been described and illustrated with respect to embodiments thereof, it should be understood by those skilled in the art that features of the disclosed embodiments can be combined, rearranged, etc., to produce additional embodiments within the scope of the invention, and that various other changes, omissions, and additions may be made therein and thereto, without parting from the spirit and scope of the present invention.
Esposito, Daniel Vincent, O'Neil, Glen Daniel
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
1771091, | |||
4377455, | Jul 22 1981 | Olin Corporation | V-Shaped sandwich-type cell with reticulate electodes |
4627897, | Jan 19 1984 | TETZLAFF, KARL-HEINZ | Process for the electrolysis of liquid electrolytes using film flow techniques |
4841731, | Jan 06 1988 | ELECTRICAL GENERATION TECHNOLOGY, INC | Electrical energy production apparatus |
5114547, | Jul 14 1989 | Permascand AB | Electrode |
5279260, | May 22 1992 | Water fuelled boiler | |
5534120, | Jul 03 1995 | Toto Ltd | Membraneless water electrolyzer |
5865966, | Jun 30 1994 | Toto Ltd. | Non-membrane electrolytic cell for electrolysis of water |
6471873, | Jan 26 2000 | SULNER, ANDREW | Electrolytic process and apparatus for purifying contaminated aqueous solutions and method for using same to remediate soil |
6719893, | Jun 11 2001 | Gunma University | Method for removing phosphorus from water to be treated using an electric field |
7439047, | Jul 10 2003 | PAQUES I P B V | Process for producing hydrogen |
7510640, | Feb 18 2004 | GM Global Technology Operations LLC | Method and apparatus for hydrogen generation |
7645931, | Mar 27 2007 | GM Global Technology Operations LLC | Apparatus to reduce the cost of renewable hydrogen fuel generation by electrolysis using combined solar and grid power |
20030006136, | |||
20040168909, | |||
20060210867, | |||
20090025315, | |||
20130175180, | |||
20150034493, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Sep 19 2016 | The Trustees of Columbia University in the City of New York | (assignment on the face of the patent) | / | |||
Jul 23 2018 | O NEIL, GLEN DANIEL | The Trustees of Columbia University in the City of New York | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 053526 | /0614 | |
Jul 24 2018 | ESPOSITO, DANIEL VINCENT | The Trustees of Columbia University in the City of New York | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 053526 | /0614 |
Date | Maintenance Fee Events |
Oct 09 2020 | MICR: Entity status set to Micro. |
May 24 2024 | M3551: Payment of Maintenance Fee, 4th Year, Micro Entity. |
Date | Maintenance Schedule |
Nov 24 2023 | 4 years fee payment window open |
May 24 2024 | 6 months grace period start (w surcharge) |
Nov 24 2024 | patent expiry (for year 4) |
Nov 24 2026 | 2 years to revive unintentionally abandoned end. (for year 4) |
Nov 24 2027 | 8 years fee payment window open |
May 24 2028 | 6 months grace period start (w surcharge) |
Nov 24 2028 | patent expiry (for year 8) |
Nov 24 2030 | 2 years to revive unintentionally abandoned end. (for year 8) |
Nov 24 2031 | 12 years fee payment window open |
May 24 2032 | 6 months grace period start (w surcharge) |
Nov 24 2032 | patent expiry (for year 12) |
Nov 24 2034 | 2 years to revive unintentionally abandoned end. (for year 12) |